EP0827302A2 - Method for isolating defective, exchangeable units of arbitrarily structured communications systems - Google Patents

Abstract

The method involves detecting and isolating faulty units (FRNU, FRPU) of a communication arrangement (KA) with a process architecture which is distributed on the units (FRNU, FRPU). Errors detected in the communications arrangement (KA) are announced through an error message (FR), and temporary consecutive errors and condition-related error messages are determined with the help of an ignore-table (FIT), and are ignored. An error class (FK1.5) is determined for error messages which can not be ignored using an error isolation table (GFIT). At a occurrence of an error message of a first error class (FK1), the unit causing the error is directly isolated using only the announced error message. In a second error class (FK2) the faulty unit is isolated using an unit information (ei) inserted in the error isolation table, in a third error class (FK3) the faulty unit is isolated using a comparison table (CT) indicated in the error isolation table, and in a fourth error class (FK4) the faulty unit is isolated using at least one system-specific error isolation procedure (SSIP), indicated in the error isolation table. In a fifth error class (FK5) the faulty unit is not isolated.

Description

In complex technical arrangements, especially communication arrangements, that of several communicating with each other and dependent units - especially interchangeable ones Assemblies - as well as higher-level units - for example Function groups - will exist if an error occurs tries the unit causing the error or functional group - to isolate, i.e. to determine. After fault isolation, automatically initiated, appropriate recovery process tried before Occurrence of the error set state of the communication arrangement restore. The recovery measures remain unsuccessful, the one causing the error or faulty unit - assembly or function group - on one Operating device of the communication arrangement alarms, to replace the faulty unit.

For complex, extensive communication arrangements that usually several processors with a distributed process architecture include, cause currently occurring circuit technology or programming errors usually several error messages, those due to consequential errors in other units the communication arrangement at different times formed and transmitted to a central fault isolation will. This means that for insulation faulty unit or assembly or function group extensive Assessment of the reported error messages required are, with special circuitry and programming Include characteristics of the communication arrangement are.

Another problem with the known fault isolation methods places its close coupling in particular on the circuitry Expression of the communication arrangement. This means that the fault localization methods implemented in the program not for communication arrangements can be used with different circuit configurations are.

The object underlying the invention is To design fault localization methods in such a way that they with as few modifications as possible for communication arrangements with a wide variety of circuit designs can be used. The task is characterized by the characteristics of claim 1 solved.

An essential aspect of the method according to the invention is to see that with the help of an ignore table error messages are determined which are ignored, i.e. not further be rated. With the help of an isolation table the further localization measures are determined, for which the Error messages are classified into five error classes. This classification and the advantageous conception an ignore and isolation table becomes an extensive one Separation of circuit-independent and dependent Fault localization measures achieved, which means that Error-localization methods implemented advantageously in terms of program technology for communication arrangements with different circuitry versions can be used. Only to special configurations of the communication arrangement the tables must be coordinated. The tables - ignore table and the fault location table - can simply by menu-driven, operational inputs on Operating terminal of the communication arrangement modified or can be configured during initial creation. With constantly shorter ones Development cycles of communication arrangements or Communication facilities, especially in the network access area of communication systems, represents the continued use of fault localization procedures or fault localization software in different communication facilities and Further developments of these facilities are essential Advantage through which both development costs as well Development times for communication facilities reduced can be.

Further advantageous refinements, in particular of the ignoring table, the insulation table and the comparison tables as well as their application are to the further claims remove.

FIG 1

in einem Blockschaltbild eine allgemeine Struktur einer Kommunikationsanordnung,

FIG 2

in einem Blockschaltbild die Tabellenkonfiguration der erfindungsgemäßen Fehlerisolierung,

FIG 3a

in einem Blockschaltbild einen Fehlerignorierungsgraph,

FIG 3b

in einem Blockschaltbild die Struktur der Ignorierungstabelle,

FIG 3c

in einem Blockschaltbild die Struktur der Vergeichstabelle,

FIG 3d

in einem Blockschaltbild die Struktur der Isolierungstabelle und

Fig. 4

in einem Ablaufdiagramm die erfindungsgemäße Fehlerisolierung.

The method according to the invention is explained in more detail below with the aid of graphic representations. Show

FIG. 1

in a block diagram a general structure of a communication arrangement,

FIG 2

the table configuration of the fault isolation according to the invention in a block diagram,

FIG 3a

in a block diagram an error ignoring graph,

3b

the structure of the ignore table in a block diagram,

3c

the structure of the comparison table in a block diagram,

FIG 3d

in a block diagram the structure of the insulation table and

Fig. 4

the fault isolation according to the invention in a flowchart.

A general, in FIG shown structure of a communication arrangement KA, for example a communication arrangement in a feeder network a communication system, provided. The communication arrangement KA is different due to different, individually interchangeable Units FRU formed, in principle, processor-controlled FRPU and non-processor controlled units FRNU units are provided. The processor-controlled units FRPU always monitor the associated, non-processor controlled units FRNU. The units FRU's communication arrangement represent the smallest interchangeable Units, for example assemblies or plug-in units, The communication arrangement further comprises a central area CU, i.e. a parent Area and a parent, peripheral or server area RA, the central area CU being defined by central, i.e. higher-level units FRU and the peripheral area RA formed by several higher-level, decentralized units FRU is. The central area CU or the central facility has four interchangeable, processor-controlled at home embodiment FRPU1..4 units and a replaceable, non-processor controlled FRNU1 unit on. The second processor controlled FRPU2 unit is with a fifth, interchangeable processor-controlled unit FRPU5 and a second as well a third non-processor controlled unit FRNU2.3 connected, the fifth processor-controlled unit FRPU5 and the second and third non-processor controlled unit FRNU2.3 a higher-level, peripheral area RA or one form a higher-level peripheral facility. The fifth processor controlled Unit FRPU5 is with other, not shown Units connected - indicated by dashed lines. The third processor controlled unit is FRPU3 each with a sixth and seventh processor-controlled Unit FRPU6.7 and a fourth non-processor controlled Unit FRNU4 connected, being connected to the processor-controlled Units FRPU6.7 further units, not shown, can be connected are - indicated by dashed lines. The fourth processor-controlled unit FRPU4 is with a fifth and sixth non-processor controlled unit FRNU5,6 connected.

Of the non-processor controlled units FRNU1..6 exist no connections to other units since one non-processor controlled unit FRNU due to the missing Processor technology cannot monitor other units FRU, especially can not receive error messages. In the 1 shows the structure of all variants of processor-controlled and non-processor controlled units FRNU, FRPU as well as assignment to higher-level central or peripheral Areas CU, RA and facilities.

Given the structure of a communication arrangement KA each error detectable in the units FRU is replaced by one processor-controlled unit FRPU detected and by represents a clear error message FR. From everyone in Area of the communication arrangement KA arranged, processor-controlled Facilities FRPU1..7 will get these error messages FR transmitted to a fault isolation FI, for example in the central area CU, i.e. in a central Device arranged or alternatively on several processor-controlled Units FRPU1..7 is distributed, the fault isolation FI essentially by the inventive method is realized. An essential aspect of fault isolation FI is the appropriate classification of all possible Errors detectable in the communication arrangement KA or Error messages FR and the assignment of ignoring, Isolation and comparison tables for an advantageous separation the fault location software into a generic one and to enable a system-specific part. Of the generic part of the software includes those parts of the program independent of communication arrangement without program changes are reusable as well as tables that correspond the current configuration of the communication arrangement are to be modified. For the configuration of the tables in particular can special software - not shown - be designed with a suitable comfortable surface for entering the table entries. As system specific Parts of the software are those program parts intended the one for isolating complex errors below Taking into account the current configuration of the communication arrangement KA must also be provided and accordingly are not generic in nature.

According to the inventive method, those in the communication arrangement KA detectable errors FR in five error classes FK1..5 classified. The first error class FK1 are assigned those error messages FR for which the the unit causing the error FRU directly from the transmitted Error message FR can be identified. The second Error class FK2 are assigned those error messages FR, where a processor-controlled unit FRPU for another, the unit causing the error, an error message FR transmitted and the one causing the error Unit FRU indirectly through the error message FR via a Table access (isolation table GFIT) can be identified can. The third error class FK3 are those error messages FR assigned where the fault isolation by comparing the error messages FR of units FRNU is carried out, these units FRU each in hierarchically the same communication arrangement level and from an error occurring from another Unit FRU in the higher level are dependent. Because only dependencies between the error messages FR in the same communication arrangement level go into this comparison, can the appropriate fault isolation by processing a appropriately structured comparison table CT. With the error messages FR of the fourth class FK4, the units causing the error FRU only by system and circuit-specific procedures - for example, more independent Test an assembly or system tests in which several Assemblies are involved - to be determined. The fifth error class FK5 includes those error messages FR, for fault isolation on a replaceable unit FRU - for example an assembly - is not possible. For These error messages are provided in a list in the LVO suspect for the non-isolable error messages FR, i.e. possibly faulty units FPNU, FRNU specified are.

2 shows the procedure for configuring the tables, provided for the fault isolation FI according to the invention are shown. Here forms the "carried out offline" Error classification is the basis of this configuration. FIG. 2 also shows the division of the software into shown a generic and a system specific part taking the generic part from the general software control structure as well as the configured tables and the system-specific Part of the communication arrangement specific Parts includes.

An error ignoring graph is provided for each possible error message FR - See FIG 3a - created. An error ignoring graph represents a graphical structure, at each specifically for an error message FR or the this error message FR reporting unit FRU the dependency of errors in higher-level units FRU (S) are graphed is. A unit FRU is shown in FIG. 3a represents a circle, being for the embodiment specific for an error message FRx or the error message FRx reporting unit FRUx is assumed to be out of two parent units FRUy (S), FRUz (S), in each of which the cause of the error occurs - for example signal or Heartbeat generation failure -, also a parent Window message FRy (S), FRz (S) is reported. This dependency is shown by the arrows shown in FIG. 3a, where the direction of the subsequent error is indicated by the direction of the arrow and an error in the unit FRU located at the beginning of the arrow - In the exemplary embodiment, the parent units FRUy (S), FRUz (S) - a consequential error in the at the arrowhead located unit FRU - in the embodiment FRUx unit - caused and generated by each of the FRUx units, FRUy (S), FRUz (S) an error message FRx, FRy (S), FRz (S) transmitted becomes. This means that a currently reported error message FRx may be ignored if one of these parent unit FRUy (S), FRUz (S) an error message FRy (S), FRz (S) is reported because of the error in the parent Units FRUy (S), FRUz (S) causes. Hence are based on the embodiment in a first Ignore table FIT1 of an ignore table shown in FIG. 3b FIT in a first column the parent Units FRUy (S), FRUz (S) and in a second column the associated ones higher-level error messages FRy (S), FRz (S) entered. In the first ignore table shown in FIG. 3b FIT1 are also the ones for all possible error messages The error ignoring graph determined for FR is shown - However, only the illustration of the previous one is exemplary explained error ignoring graph.

As previously explained, the first column is the first Ignition table FIT1 specific for an error message FR, the parent units FRU (S) are given, the one that is the cause of the error message FR can have. They are in a second column corresponding higher-level error messages FR (S) for this causal error specified. Therefore, in addition to the error message FR such a higher-level error message FR (S) transmitted to the fault isolation, it represents this Error message FR not the unit causing the error FRU and can therefore be ignored. The causal error is represented here by the higher-level error message FR (S). Was not one of those in the first ignore table FIT1 listed parent error messages FR (S) received, it is examined whether in a second ignore table FIT2 of the ignore table FIT - see FIG 3b - Function names FN1..n associated with the error message FR specified are. If so, these functions are sequential called. With the help of the system-specific functions become communication arrangement-specific states determined, for example, operating states of special Units FRU. Depending on the determined operating conditions can be decided whether the error message received FR can be ignored. For example, a inactive assembly cause other assemblies to be special Issue error messages FR that can be ignored.

According to the inventive method, as explained above, the possible error messages FR in five Error classes FK1..5 classified. The result of the classification is entered in the fault isolation table GFIT, an error class for every possible error message FR FK1..5 is entered. In the method according to the invention the GFIT insulation table provides the essential table is used to control the isolation of the error message FR becomes.

FIG 3d shows the basic structure of the insulation table GFIT. The first two of a total of five columns in the fault isolation table GFIT included for each by one Errors in the communication arrangement KA caused an error message FR the unit transmitting the error message FR FRU. The prerequisite for this is that the error messages FR in the communication arrangement KA in a uniform form be reported. The content of these two columns forms the Search key for the table to get the one on isolating - and not ignorable - error message FR in the GFIT insulation table in accordance with the information stored to find or initiate actions.

In another column are the respective error messages Waiting time information assigned to FR can be entered. By this waiting time information wti is given while which after receiving a specific error message FR on the Receive further, possibly causal error messages FR must be waited for before making a final decision ignoring the current error message FR can be. The next column is the Error class FK1..5 specified for which the respective error message FR is classified. In the insulation table shown GFIT are the error messages FR according to the function classes FK1..5 ordered.

• Bei der Fehlerklasse FK1 sind keine zusätzlichen Informationen rem eingetragen, da die den Fehler verursachende Einheit FRU direkt durch die übermittelte Fehlermeldung FR isoliert wird.
• Bei einer angegebenen zweiten Fehlerklasse FK2 ist durch Angabe einer Einheiteninformation ei die den Fehler verursachende Einheit FRU indirekt bestimmt, d.h. isoliert.
• Bei einer angegebenen dritten Fehlerklasse FK3 ist ein Tabellenname eingetragen, durch den eine Vergleichstabelle CT bestimmt ist, mit deren Hilfe die einen komplexen Fehler verursachende Einheit FRU ermittelt werden kann.
• Bei einer angegebenen vierten Fehlerklasse FK4 ist ein Prozedurname angegeben, der eine systemspezifische, d.h. kommunikationsanordnungs-spezifische Prozedur SSIP identifiziert, mit deren Hilfe die den Fehler verursachende Einheit FRU isoliert wird.
• Bei Fehlermeldungen FR der fünften Fehlerklasse FK5 kann die den Fehler verursachende Einheit FRU nicht isoliert werden, jedoch ist als eine zusätzliche Information rem eine LVO-Information eingetragen, durch die eine Liste von verdächtigen, d.h. fehlerverdächtigen Einheiten FRNU, FRPU adressiert ist. In dieser Liste LVO sind für die Fehlermeldungen FR der fünften Fehlerklasse FK5 die Einheiten FRU angegeben, die bei der angegebenen Fehlermeldung FR fehlerverdächtig sind, d.h. den Fehler verursachen können. Eine eindeutige Fehlerisolierung FI ist bei Fehlern dieser Klasse aufgrund der kommunikationsanordnungs-spezifischen Gegebenheiten nicht möglich oder entsprechende Fehlerlokalisierungsprozeduren sind noch nicht realisiert.

In the last column, the following additional information essential to the invention is given for the entered error messages FR depending on the specified error class FK1..5:

• No additional information rem is entered in the error class FK1, since the unit FRU causing the error is isolated directly by the transmitted error message FR.
• In the case of a specified second error class FK2, the unit FRU causing the error is indirectly determined, ie isolated, by specifying unit information ei.
• In the case of a specified third error class FK3, a table name is entered by which a comparison table CT is determined, with the aid of which the unit FRU causing a complex error can be determined.
• If a fourth error class FK4 is specified, a procedure name is specified which identifies a system-specific, that is to say communication arrangement-specific procedure SSIP, with the aid of which the unit FRU causing the error is isolated.
• In the case of error messages FR of the fifth error class FK5, the unit FRU causing the error cannot be isolated, but LVO information is entered as additional information rem, by means of which a list of suspect, ie error-suspect units FRNU, FRPU is addressed. In this list LVO, the units FRU are specified for the error messages FR of the fifth error class FK5, which are suspect in the error message FR specified, ie, can cause the error. A clear fault isolation FI is not possible in the case of faults of this class due to the conditions specific to the communication arrangement or corresponding fault location procedures have not yet been implemented.

Variante a: Die verbleibenden, von den übergeordneten Einheiten FRU(S) abhängigen Einheiten FRU melden ebenfalls die äquivalenten Fehlermeldungen FR. Dies bedeutet, daß der ursächliche Fehler auf die übergeordnete Einheit FRU(S) zu isolieren ist, obwohl keine Fehlermeldung FR für diese Einheit FRU(S) übermittelt ist.

Variante B: Die bestimmte Einheit FRU ist die einzige von mehreren übergeordneten Einheiten FRU(S), die einen Fehler meldet. Dies bedeutet, daß der ursächliche Fehler auf die bestimmte Einheit FRU zu isolieren ist.

Variante c: Der Fehlerstatus der verbleibenden abhängigen Einheiten FRU kann nicht abgefragt werden. Dies ist beispielsweise der Fall bei nicht konfigurierbaren und inaktiven Einheiten FRU. Da der Fehler folglich nicht eindeutig isolierbar ist, werden die verdächtigen Einheiten FRU in eine Liste LVO eingetragen, deren Name ebenfalls in der zweiten Vergleichstabelle CT2 abgelegt ist.

The comparison table CT shown in FIG. 3c is composed of two different comparison tables CT1,2, the first comparison table CT1 corresponding in structure to the ignoring table FIT1. For each error message FR of the third error class FK3 there is a pair of tables CT1,2. In contrast to the ignoring tables FIT1.2, the two comparison tables CT1.2 represent the image of a single superordinate unit FRU (S) and several units FRU dependent thereon. In the two columns of the first comparison table CT1, all units FRU1..x and corresponding ones Error messages FR1..x entered that are transmitted in the higher-level unit FRU (S) when a certain error occurs. These error messages FR1..x consequently represent subsequent error messages FR of this causal error in the unit FRU (S), which are entered in the second comparison table CT2. Since this higher-level unit FRU (S) did not report the causal error - a reported error FR would otherwise have been ignored in the previous error-ignoring process - when an error message FR, which belongs to the third error class FK3, occurs with regard to the error messages FR (i) three options:

Variant a: The remaining units FRU, which are dependent on the higher-level units FRU (S), also report the equivalent error messages FR. This means that the causal error must be isolated on the higher-level unit FRU (S), although no error message FR has been transmitted for this unit FRU (S).

Variant B: The specific unit FRU is the only one of several higher-level units FRU (S) that reports an error. This means that the causal error must be isolated to the specific unit FRU.

Variant c: The error status of the remaining dependent units FRU cannot be queried. This is the case, for example, with non-configurable and inactive units FRU. Since the error cannot therefore be clearly isolated, the suspect units FRU are entered in a list LVO, the name of which is also stored in the second comparison table CT2.

The isolation of error messages FR of the third error class FK3 can be done by systematic processing of the two comparison tables CT1.2.

An essential aspect of the method according to the invention is to be seen in the fact that the tables explained above, especially ignore table FIT, fault isolation table GFIT and the comparison table CT the generic Part of the fault isolation software or the fault isolation program structure assigned. This means that the Control software for processing these tables also at different forms of communication arrangement can be used unchanged and only the tables FIT, GFIT, CT on the corresponding configuration of the communication arrangement KA are to be adjusted. Are for creating these tables FIT, GFIT, CT with the help of additional programs comfortable user interfaces can be implemented Effort for customizing the generic part of the software to the respective configuration of the communication arrangement KA be minimized. The system specific part of the software is consequently limited to those programs that are specific Functions through the appropriate form of the communication arrangement KA are matched. These special functions or implement special programs FIP, SSIP on the fault isolation communication-specific Ignore and isolate procedures, with the specific Isolation procedures are required to SSIP with complex errors, i.e. Error messages FR that of the fourth Error class FK4 are assigned to the unit FRU with the to determine the cause of the error.

The following is based on the flow chart shown in FIG 4 the method according to the invention explained in more detail. The fault isolation FI is caused by a in the communication arrangement KA transmitted error message FR started. In the error message FR indicates from which unit FRU the error message FR was transmitted or in which this was formed. Using the first and second ignore tables FIT1.2 is now examined whether the transmitted Error message FR is to be ignored. For this purpose, it is checked whether one in the first column of the first ignore table FIT1 specified higher-level unit FRU (S) already has an associated one Error message FR (j) in the second column of the first Ignition table FIT1 is available. Is if this is the case, the error message FR can be ignored, since it is a subsequent error message FR of the error of the parent Unit FRU (S) represents.

If the error message FR cannot be ignored, it is checked whether whether in the isolation table GFIT for this error message FR a waiting time information wti is entered. Is this is the case after the expiry of the waiting time information wti specified waiting time wt the first ignore table FIT1 processed again in the same way. By this waiting time information wti it is possible for further error messages FR, which is delayed in the communication arrangement KA reported to be included in the investigation. This measure is necessary because a previously reported Errors are a consequential error of a later reported error can be.

Can the received error message FR after the waiting time will not be ignored, the second ignore table FIT2 checks whether one or more function names FN1..n are specified. When a function name is found FN1..n are the assigned functions successively called. With the help of these functions Communication arrangement-specific states, for example States of the respective units FRU determined. The results of the investigation are an indication of whether the transmitted Error message FR can be ignored or not.

Results in the described investigation using the first and second ignore table FIT1,2 that the transmitted error message FR cannot be ignored, is from the isolation table GFIT assigned to this error message FR Error class FK1..5 determined. If the error message FR is the assigned to the first error class FK1, so represents in the error message FR specified unit FRU that FRU unit that is causing the error. The error is therefore on one interchangeable unit FRU isolated, for example, an assembly.

With a specified assignment of the currently transmitted Error message FR for the second error class FK2 is in the Isolation table GFIT for the respective error message Fault-causing unit FRU of the communication arrangement KA indicated by unit information ei and thus isolated.

Is it the currently transmitted error message FR for an error message FR of the third error class FK3, see above is calculated using a first and second comparison table CT1,2 formed the comparison table CT the error causative unit FRU isolated. For this purpose, the Entries in the first comparison table CT1 - where the current transmitted error message FR one of these entries corresponds - examines whether this relates to the error message FR units in the same hierarchical level FRU have also transmitted the equivalent error messages FR. If this is not the case, it is in the currently transmitted Error message FR specified unit FRU as the faulty unit FRU isolated. However, if this is the case, the fault is caused by the higher-level unit FRU (S) and is on this unit FRU (S), whose name in the first line of the second comparison table CT2 entered is isolated. Can the mistake be made using the first and the second comparison table CT1,2 cannot be isolated, so the currently transmitted error message FR is not isolatable on an output device - not shown - the Communication arrangement KA issued. Furthermore, the suspect units entered in the LVO list FRU output, the name of this list on the second line the second comparison table CT2 is given.

Given a classification of the currently transmitted Error message FR for the fourth error class FK4 is in the GFIT isolation table for the respective error message For SSIP information entered. With this SSIP information are identifications by which error-specific, specifically on the circuit technology of the current Configuration of the communication arrangement KA related Fault isolation procedures called and executed SSIP will. These system-specific fault isolation procedures SSIP are based on the special circuit-technical characteristics matched the respective communication arrangement KA and are specially designed for the respective communication arrangement KA designed or developed. Such fault isolation procedures include, for example, special unit tests or system test in which several units FRU the communication arrangement KA are involved - e.g. Loop tests. After execution of the specific assigned to the error message FR Fault isolation procedures SSIP is the fault causative unit FRU isolated.

With a small number of error messages FR is one Isolation to a replaceable FRU unit not possible because e.g. specific tests, their implementation for insulation the error is required by the units FRU of the communication arrangement KA are not provided. These error messages FR are the fifth error class FK5 assigned. For the error messages FR of the fifth error class FK5 is an LVO information in the GFIT isolation table specified that on a list of LVO suspect Units FRU indicates. The one in the LVO list for each error message FR of the fifth error class FK5 suspect FRU units are sent to an output device the communication arrangement KA output.

The fault isolation FI shown in FIG. 4 is, for example in a fault isolation routine in the central area CU or in the central unit of the communication arrangement KA realized. The fault isolation FI is alternatively through several subroutines in higher-level areas RA of the communication arrangement KA feasible.

Claims (9)

Method for isolating faulty units (FRNU, FRPU) of a communication device (KA) with a process architecture distributed to the units (FRNU, FRPU), where every error detected in the communication device (KA) is reported by an error message (FR), in which temporary follow-up and condition-specific error messages (FR) reported with the help of an ignoring table (FIT) are determined and ignored, in which the error class (FK1..5) of the current, non-ignorable error messages (FR) is determined with the aid of an error isolation table (GFIT) for each error message (FR) that cannot be ignored (FR), and in which an error message (FR) on the unit causing the error (FRNU, FRPU) - for the first error class (FK1) directly using the reported error message (FR), - for the second fault class (FK2) with the help of unit information (ei) inserted in the fault isolation table (GFIT), - for the third fault class (FK3) using a comparison table (CT) specified in the fault isolation table (GFIT), - in the fourth fault class (FK4) is isolated using at least one system-specific fault isolation procedure (SSIP) specified in the fault isolation table (GFIT) and - In the fifth error class (FK5) the faulty unit cannot be isolated. Method according to Claim 1, characterized in that a first and a second ignoring table (FIT1,2) is provided in the ignoring table (FIT) for each error message (FR), whereby in the first ignore table (FIT1) for the higher-level units (FRNU (S), FRPU (S)) the higher-level error messages (FR (S), and In the second ignoring table (FIT2) the function names (FN1..n) of function are specified, which are intended for the determination of special, ignorable error messages (FR). Method according to Claim 2, characterized in that, in the case of a currently reported error message (FR), the first ignoring table (FIT1) and at least temporarily stored, already reported error messages (FR) are used to check whether there is already a higher-level one than the current error message (FR) Error message (FR (S)) is reported and in the case of a higher-level error message (FR (S)) that has already been reported, the currently reported error message (FR) is ignored, and
that, in the case of an unreported, higher-level error message (FR (S)), within an error message-specific waiting time (wt) specified in the error isolation table (GFIT), it is checked whether an overriding error message (FR (S)) is reported for the current error message (FR) and if a higher-level error message (FR (S)) is reported, the currently reported error message (FR) is ignored. Method according to Claim 3, characterized in that in the case of a currently reported error message (FR) in the case of a non-reported higher-level error message (FR (S)) within a waiting time (wt) specific to the error message, the function names (FN1 ..) in the second ignoring table (FIT2) n) identified functions for determining the ignoring of the current error message (FR) are carried out and the current error message (FR) is ignored or not ignored in accordance with the determination result. Method according to one of claims 1 to 4, characterized in that in the error isolation table (GFIT) for each unit (FRNU, FRPU) and the error message indicating the error which occurs in the communication device (KA) and which indicates the error message (FR). a unit (FRNU, FRPU) reporting the error message (FR) and the error message (FR) indicating the error, the error class (FK1..5), and an error class-related additional information (rem) is entered. Method according to Claim 5, characterized in that in the case of a current, non-ignitable error message (FR), this and the unit (FRNU, FRPU) reporting the error message (FR) determine the error class (FK1..5) from the error isolation table (GFIT) is that when the current error message (FR) is assigned to the first error class (FK1) the unit causing the error (FRPU, FRNU) directly through the error message (FR), and the second error class (FK2) the unit causing the error (FRPU, FRNU) is isolated indirectly by the additional information (rem) assigned in the isolation table (GFIT), the third fault class (FK3) the isolation is carried out by processing the comparison table (CT) determined from the additional information (rem) assigned to the isolation table (GFIT), the fourth fault class (FK4) the isolation is carried out by executing at least one of the system-specific fault isolation procedures (SSIP) determined by the additional information (rem) assigned in the isolation table (GFIT), and the fifth error class (FK5) the faulty unit (FRNU, FRPU) cannot be isolated. Method according to one of claims 1 to 6, characterized in that in the comparison table (CT) consisting of a first and second comparison table (CT1,2), the first comparison table (CT1) is provided in order to enter all the same units (FRU (1..x)) that are in the same hierarchy level as the error messages (FR) and the associated error messages (FR (1..x)) that occur when they occur of predetermined errors from the affected, higher-level unit (FRNU (S), FRPU (S)) are transmitted, and the second comparison table (CT2) is provided in order to enter the units (FRNU (S), FRPU (S) superordinate with respect to the units (FRU (1..x) entered in the first comparison table (CT1). Method according to Claim 7, characterized in that in the case of a currently reported, non-ignitable error message (FR) of the determined third error class (FK3) in the presence of the equivalent error messages (FR) specified in the first comparison table (CT1) with the aid of the second comparison table ( CT2) the higher-level, faulty unit (FRNU, FRPU) of the communication arrangement (KA) is isolated, and that, in the absence of the equivalent error message (FR) specified in the first comparison table (CT1), the faulty unit (FR) due to the current error message (FR) FRNU, FRPU) is isolated. Method according to one of the preceding claims, characterized in that in a list (LVO) for those error messages (FR) for which no faulty unit (FRNU, FRPU) could be clearly isolated, indications of suspect, faulty units (FRNU, FRPU) are entered, and that in the case of a current error message (FR) with the determined fifth error class (FK5), the suspect units (FRPU, FRNU) entered in the list (LVO) are determined and output.

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